Core-shell SnSe@TiO2/C heterostructure high-performance anode for Na-ion batteries

The core-shell SnSe@TiO2/C heterostructure composite with high reactivity, small size, and superior elec-trochemical performance for sodium-ion batteries (SIBs) was synthesized for the first time using a controllable arc-discharge technique. The electrochemical measurements demonstrate that the outstanding mechanical stability of the TiO2 shell can improve the cycling stability, rate capability, and high specific capacity of SnSe. The as-prepared core-shell SnSe@TiO2/C composite combines the benefits of SnSe and TiO2, with SnSe nanoparticles improving ion diffusion kinetics and specific capacity while TiO2 maintains excellent cycling stability. Furthermore, the core-shell heterostructure approach can synergistically reduce volume fluctuation and aggregation of active materials during cycling. At a current density of 1 A/g, the capacity can reach 318 mAh/g, with a steady cycling performance of 1100 cycles. The novel core-shell heterostructure composite is expected to be a promising candidate as an anode material for next-generation high-performance SIBs due to its outstanding electrochemical performance and ease of synthesis for large-scale production. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

The core-shell SnSe@TiO2/C heterostructure composite demonstrates high reactivity and superior electrochemical performance in sodium-ion batteries. The TiO2 shell enhances the mechanical stability of SnSe, while the synergistic effects of the core-shell structure optimize ion diffusion kinetics and cycling stability. This novel composite shows promising potential as an anode material for high-performance SIBs.